Wide field-of-view digital night vision headmounted

Wide field-of-view digital night vision headmounted display a Michael P. Browne* SA Photonics, 915-D Terminal Way, San Carlos, CA 94070; 1. INTRODUCT...
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Wide field-of-view digital night vision headmounted display a

Michael P. Browne* SA Photonics, 915-D Terminal Way, San Carlos, CA 94070; 1. INTRODUCTION

Night vision has been a key enabling technology for the past 30 years that has allowed US pilots to “own the night”. In many engagements, our dominance of the nighttime environment was the decisive factor in victory. One of the big disadvantages of night vision systems is that they have not provided pilots with good peripheral vision, since most have a total field of view (TFOV) of only 40 degrees. A large survey of USAF pilots found that the most often requested improvement to night vision goggles was to have a larger field of view. 1 Wide field of view night vision goggles, such as the PNVG and QuadEye systems were designed to address this need. In the 15 years since the PNVG was designed, tremendous advances have been made both in microdisplay technology and high-resolution digital night vision sensors, which enable a new class of wide field of view digital night vision systems. SA Photonics has developed a wide field of view digital night vision system for use by fixed-wing and rotorcraft pilots. This system can be attached to off-the-shelf aviator helmets and provides significant advantages compared to existing night vision goggles. The results of the design and preliminary testing of this HMD are given below, along with a discussion of future upgrades to the system.

2. HRNVS OVERVIEW The 82.5 degree high resolution night vision system (HRNVS) module developed by SA Photonics is shown in Figure 1. This design was driven by our goals to 1) improve resolution, 2) reduce weight, 3) improve center of gravity, 4) reduce forward projection and 5) reduce peripheral obscurations compared to existing conventional wide field of view night vision systems, while providing the advantages of a digital night vision system. HRNVS utilizes two solid-state digital night vision sensors per eye and couples them to a single high-resolution microdisplay. By designing an eyepiece without tiles or seams, the user will have a panoramic view of the night vision imagery without the visual distractions caused by using multiple displays or eyepiece optics per eye. 2.1 HRNVS features There are a number of advantages in having a digital high resolution, wide field of view night vision system like the HRNVS. These include: Reduced peripheral obscuration. As can be seen in Figure 1, there Figure 1: HRNVS Prototype are very little obscurations in the operator’s field of view besides the small eyepieces. This design preserves much of the operator’s up and downlook, especially compared to ANVIS and PNVS systems. HRNVS has a much reduced forward projection and swept volume than the ANVIS or PNVG systems. This will allow the operator to perform aggressive head maneuvers without worrying about striking the canopy *[email protected]; phone 1-408-348-4426; saphotonics.com

Increased performance. An 80 degree field of view provides much better situational awareness than current ANVIS night vision goggles do. The increased optical performance will mean that when a pilot pulls Gs the imagery will not degrade unlike existing panoramic night vision goggles under g-load. Zero-halo. The digital night vision sensors have a proprietary halo reduction structure that reduces halo around bright light sources to near-zero. Ability to stow each eyepiece independently. HRNVS has independently stowable eyepieces and a novel stowage mechanism. Instead of flipping upwards like ANVIS or the PNVG system, making a too-high, tooforward CG even worse, the combiners on HRNVS simply pivot out of the way, hardly changing CG at all. In the stowed position the HRNVS does not block the operator’s peripheral vision at all, what they see is just determined by the extent of the helmet. Capability for image enhancement. A digital night vision system provides the ability to enhance night vision imagery by contrast/edge enhancement, speckle reduction, symbology overlay and video recording, none of which are possible with existing night vision systems. We will implement these features on the next-generation HRNVS, discussed in Section 5. 2.2 HRNVS architecture Figure 2 is a block diagram for the HRNVS system. The major subassemblies are: Digital night vision sensors Custom objective lens with stray light rejection Video processor and electronics Helmet mounting system Adjustment system Digital microdisplay Eyepiece optics There are four night vision sensors, two left and two right. Each sensor has an objective lens to focus the object. Each pair of sensors is processed into a single video stream which is fed into each eyepiece. Each eyepiece consists of a microdisplay and eyepiece optics. The adjustment system positions each eyepiece independently for each user and the helmet mounting system attaches the HRNVS to any standard flight helmet via a custom interface kit. Each of these systems will be discussed in more detail in the next section.

Figure 2: HRNVS Block Diagram

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HRNVS’ 80 degree field of view is achieved through partial binocular overlap. The architecture is shown in Figure 3. The top of the figure shows the layout of the night vision sensors and the bottom part of the figure shows the layout of the eyepieces.

Diagonal FOV of Objective Lens at 40 deg

OBJECTIVE & EYEPIECE LENS

Eyepiece FOV 30x55 dg

Left Eye

Right Eye

55 deg

55 deg

30 deg

30 deg

27.5 deg

27.5 deg

OVERLAP FOV

(with IIT sensor completely filled & Underfilled Eyepiece FOV) 82.5 deg

27.5 deg

27.5

27.5

30 deg

Left Eye

Right Eye 13.75 deg Cant Angle

Figure 3: HRNVS Field of View and Layout The night vision sensors each have a horizontal field of view of 27.5 degrees and two night vision devices feed into each 55 degree eyepiece. Each square represents the used area of the night vision sensor and the dashed circle represents the field of view of the objective lenses, which overfill the sensor. Each eyepiece has a 55 degree horizontal field of view and is overlapped by 27.5 degrees. The eyepieces are canted at a 13.75 degree angle so that the field of view is centered with respect to the eyepiece.

3. SYSTEM DESIGN Each of the subsystems listed in the previous section will be discussed in more detail below. System performance will be discussed in the following section. 3.1 Digital night vision cameras The digital night vision cameras are Intevac Model ISIE 11 EBAPS (electron bombarded active pixel sensors). They have a GaAs photocathode, just like standard Gen III night vision goggles. Behind the photocathode is a Silicon CMOS sensor, which provides the digital output. A high voltage potential is applied between the photocathode and the sensor. This voltage accelrates photoelectrons and provides gain when the photoelectrons strike the sensor. The ISIE 11 sensors consist of 1600 x 1200 square pixels arranged on a regular grid. There is a finite spread as the electrons are imaged, which reduces the resolution or modulation transfer function (MTF) of the sensor, as will be shown in Section 4.

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The Intevac ISIE 11 camera consists of 5 boards, which we removed from their original housing and repackaged within our HMD. We designed a set of custom flex cables to connect the boards together (they are normally connected in a camera via edge card connectors) in an orientation such that they fit in our HMD housing. We also designed a set of custom jumper cables to replace the shorter jumper cables that are standard on this camera. The end result is a digital night vision camera that can be folded up to fit within an HMD housing. 3.2 Custom objective lens with stray light rejection The objective lens for the HRNVS has been custom designed for the EBAPS sensor by SA Photonics. This objective lens has very good performance over the entire field of view and has been designed with a wide chromatic bandwidth so it can operate well both with NVIS filtering and unfiltered. The measured performance of this lens is given in Table 1. Table 1: HRNVS Objective Lens Performance Objective Lens Parameter Diagonal Field of View

Value 40 degrees

F/#

1.25

Bandwidth Maximum Distortion Relative Illumination Veiling Glare

400-900 nm

Focus Range

12” to infinity

-5.2% 75% 0.4%

Comments Can be used with any 18 mm night vision imager, analog or digital A fast F/# provides for high sensitivity in low ambient light environments Provides good performance for unfiltered operation Compensated by eyepiece distortion and electronically The edge of the field is only 25% less bright than the center. Provides very good stray light performance Allows for use inside of cockpits and cargo areas as well as viewing outside the aircraft

It has been reported to us by the Air Force that current night vision goggles can have a problem with veiling glare due to “excess leakage” in the night vision goggle NVIS Class C (leaky green) filters. This is so because the Class C filter is designed to let only a small amount of green light through from the HUD when viewed on-axis. Off axis, the filter shifts its wavelenth response, allowing excess green light to leak in, which reducies the contrast of the night vision goggle. We have designed the HRNVS lens to have two filter positions. The first position is at the front of a lens, where users may easily add standard NVIS filters. The second is at the rear of the lens. This rear filter position uses the objective lens housing itself to reduce the incident angles to the filter, thereby reducing any “leakage” seen from cockpit displays. This filter is removable, but should be done in a clean environment (not in the field). We believe that this design will prove beneficial to all users who use the Class C filter. We have made a set of Class C rear-mounted filters and intend to test them in an operational environment. 3.3 Video processor and electronics To maximize the benefit from a digital night vision system, a high speed video processing system is needed. Because we wanted to be able to retrofit this system easily into existing airframes, we did not want a system that would need a large electronics box installed into the aircraft. As such, we needed a state of the art video processing system that could be mounted on the helmet or in a chest pack eventually. Rockwell Collins Display Systems (RCDS) is developing their MicroCore™ system with funding from Vision Systems International (VSI) and the U. S. Government. MicroCore™ will provide on-helmet processing technology key to producing a high resolution digital vision system. HRNVS currently uses a desktop electronics unit (DEU) which contains a prototype version of the MicroCore™ processor. These electronics will eventually be implemented in a chest pack or in the HMD fairing. The electrical system block diagram and data path is shown in Figure 4. The electrical system consists of the 4 sensors which send imagery to the MicroCore video processor. This video processor then outputs imagery to the left and right displays. In

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addition to tiling the two sensors per eye into a single display, the DEU also performs digital distortion correction and image resizing and resampling.

Figure 4: HRNVS Desktop Electronics Unit Block Diagram Shown in the block diagram are the five boards that are part of each Intevac camera. Future HRNVS systems will have a reduced board count, but to minimize program risk we just repackaged the Intevac boards as-is, using custom mounts, flex cables and jumper cable sets designed by SA Photonics. The interconnection between these five boards is shown in Figure 5.

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Figure 5: Interconnect Diagram Showing SA Photonics-designed Custom Flex Cables and Jumper Cables The power distribution system consists of a single input voltage which is then regulated to supply the sensors, displays and video processor. 3.4 Helmet mounting system The helmet mounting system allows the HRNVS to attach directly to an HGU 55 or 56/P helmet via an interface kit that uses a standard night vision goggle mounting plate attachment, as shown in Figure 6. We are also developing a kit to interface to an HGU-84/P, SPH-4/5 and the next generation of two-part helmets like the MACH helmet.

Figure 6: HRNVS Mounting Kit 3.5 Adjustment system The adjustment system adjusts the fore/aft, vertical and interpupillary distance (IPD) of the displays. It has been designed to address the widest possible range of users, based on anthropometric studies done by both the USAF and the Army. The adjustments were designed to be easily operated one-handed with a gloved hand. The adjustment ranges are shown in Table 2. Since the stowed postion, shown in Figure 7 is flat against the side of the helmet, and because we minimized the forward projection of HRNVS, the total swept volume, as shown in Figure 8, is much less than for PNVG or ANVIS. This means that pilots will have more freedom to turn their heads in the cockpit (especially for a “check 6” manoeuver) without worrying about impacting the canopy in either the deployed or stowed mode.

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Figure 7: HRNVS with stowed eyepieces has no peripheral obscuration and a very low swept volume

Figure 8: Both the Stowed and Deployed HRNVS System Have a Reduced Swept Volume Compared to ANVIS and PNVG

The adjustment range for the fit system is shown in Table 2. These adjustments have been designed to address the 1 st percentile female through 99th percentile male population.

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Table 2: HRNVS adjustment range.

Adjustment Interpupillary Distance (IPD) Vertical Fore/Aft

Range (mm) 55-75 36 36

3.6 Digital microdisplay We have selected eMagin’s SXGA (1280 x 1024 pixel) OLED display as the microdisplay source for HRNVS. This display has a small size and requires no front or backlight, which reduces the size and weight of the eyepiece, as well as simplifies the packaging and electronics requirements. The eMagin display (like many color microdisplays) has a pixel (shown in Figure 10) that consists of 3 sub-pixels, one for each primary color. Using an eMagin display without the color filters allowed us to have a almost 4 megapixel display with 3840 (3 x 1280) by 1024 pixels per eye. Since these pixels were rectangular, we needed an anamorphic eyepiece to stretch them horizontally. This eyepiece is described in the next section. 3.7 Eyepiece optics

Figure 9: Striped Pixel Configuration (one pixel is shown inside bold line at upper left)

Using the eMagin eyepiece without color filters would yield a display with three times as much resolution in the horizontal direction than the vertical direction for a given magnification. To stretch the horizontal pixels from a rectangular to a more square profile, we developed a patent pending anamorphic eyepiece which has a horizontal magnification that is greater than its vertical magnification, this helps balance out the vertical and horizontal resolution and allows for a large horizontal field of view. This eyepiece is very compact (46 mm wide x 28 mm high x 42 mm deep) and has good optical performance, as shown in Table 3.

Eyepiece Lens Parameter

Value

Horizontal Field of View

55 degrees

Vertical Field of View

30 degrees

Focus

-0.5 Diopter

Eye Relief Distance

25 mm

On-axis Exit Pupil Diameter

11.5 mm (vertical) 8.5 mm (horizontal)

Exit Pupil Diameter at Full-field

7 mm

Table 3: HRNVS Eyepiece Performance Comments This large horizontal field of view, combined with a partial binocular overlap, provides for a very large 82.5 degree system horizontal field of view Vertical field of view is limited by the number of pixels on the microdisplay, improvements are planned to increase this resolution and field of view, as is discussed in Section 5 A fixed focus eyepiece avoids the problems seen in variable focus night vision goggles. The -0.5 diopter distance was chosen because it represented a balance between infinity focus and the -0.75 diopters average setting selected by pilots for best performance in the ANVIS system2 This eye relief distance provides sufficient clearance for personnel wearing military spectacles. The horizontal exit pupil diameter was within our measurement accuracy of the design value of 12 mm. The vertical exit pupil diameter was smaller than we expected, but will still give good performance. We will address increasing this in our next-generation design. 7 mm was also our design value, which will provide good performance at the edge of the field.

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4. SYSTEM PERFORMANCE We have completed the testing of the HRNVS system. The results of these tests are given in Table 4. We believe that this is the first wide field of view digital night vision system ever built and we were very pleased with the performance of this initial prototype. We discuss potential improvements to the system in Section 5. Table 4: HRNVS System Performance Specification Horizontal Field of View Vertical Field of View Binocular Overlap Pixel Count Forward Projection Halo Diameter Distortion (compensated)

Value 82.5 degrees 30 degrees

27.5 degrees 7.9 Mpix total

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